Reduction in the virulence of mycrobacterium tuberculosis and protection against tuberculosis by means of phop gene inactivation

ABSTRACT

The construction of a mutant in the phoP gene by means of homologous recombination from a clinically isolated  Mycobacterium tuberculosis  reduces the virulence thereof in mouse bone marrow macrophage. Moreover, the phoP mutant reduces the virulence thereof in the experimental mouse model. Said phoP mutant can persist without being eliminated both in the macrophage and in the mouse. Mice inoculated with the phoP mutant are protected against  M. tuberculosis  infection. The use of mutants of mycobacteria in which the phoP gene or the genes regulated by phoP have been inactivated are candidates for vaccines against human and animal tuberculosis as well as possible recombinant vaccines against other pathogens.

TECHNICAL FIELD

This invention pertains to the field of microbiology.

BACKGROUND OF THE INVENTION

Recent developments of genetic tools for manipulating the tuberculosis bacillus make possible the construction of mutants in specific genes.

In other intracellular pathogen microorganisms such as Salmonella it has been described that the phoP gene is involved in the virulence. Inactivation of this gene has permitted the construction of attenuated mutants, which have been studied as vaccines against Salmonellosis in humans.

Our preliminary results (University of Zaragoza) in strains of the M. tuberculosis complex isolated from humans have indicated that possibly the most virulent strains have an alteration of the gene annotated in the M. tuberculosis genome as phoP.

The gene was inactivated in clinical isolation for the purpose of studying the involvement of phoP in M. tuberculosis virulence and its multiplication ability and persistence in macrophage and mouse.

DESCRIPTION OF THE INVENTION

Vectors were constructed where the phoP gene of M. tuberculosis was inactivated by the introduction of a gene resistant to kanamicine. The vectors were transformed into a clinical isolate of M. tuberculosis and a strain with the inactivated phoP gene was obtained.

Details of such constructions are contained in the 1998-1999 workbooks of the Genetics Micobacteria Group laboratories of the University of Zaragoza and the Unité de Génétique Mycoctérienne of the Pasteur Institute of Paris.

The phoP mutant of M. tuberculosis has been deposited in the culture collection of the Pasteur Institute of Paris (I-2622), 28, rue du Dr. Roux, 75724 Paris Cedex 15, France, on Nov. 27, 2000.

When M. tuberculosis was studied and compared with the mutant M. tuberculosis phoP strain for 7 days in mouse bone marrow macrophages, it was observed that the mutant was not able to replicate in mammal macrophage. By continuing with the culture of the mutant for 14 days, it was observed that it was able to persist.

After infecting a mouse with the mutant strain, it was observed that there is no multiplication of the bacillus at 3 weeks or at 6 weeks, but the number of bacteria in the spleen, the liver, and the lungs is not reduced as compared with the initial inoculation.

The results of experiments with the M. tuberculosis phoP in macrophage and mouse are contained in the workbooks of the Genetics Mico-bacteria Group laboratories of the University of Zaragoza and the Unité de Génétique Mycoctérienne of the Pasteur Institute of Paris for the year 2000.

The mouse protection studies should be added to these results. The M. tuberculosis phoP mutant was inoculated subcutaneously. Eight weeks later, the mice were intravenously infected with M tuberculosis H37Rv. Bacterial count 4 weeks after infection clearly shows that the phoP mutant protects against the multiplication of M. tuberculosis with an effectiveness comparable to the BCG vaccine control. The results of the experiments are contained in the workbooks of the Unité de Génétique Mycoctérienne of the Pasteur Institute of Paris for the years 2001-2002.

DESCRIPTION OF FIGURES

FIG. 1 shows the protection of the M. tuberculosis phoP mutant against infection with M. tuberculosis H37Rv.

Balb/c mice were inoculated subcutaneously with 10⁷ colony forming units (CFUs) either of BCG control vaccine against tuberculosis or of candidate for vaccine of the M. tuberculosis phoP mutant.

Eight weeks later, the mice were infected intravenously with M. tuberculosis H37Rv (10⁵ CFUs). Four weeks after infection, the animals were sacrificed and CFUs were counted in the spleen (FIG. 1A) and the lungs (FIG. 1B). Each value represents the geometric average ±SEM. 

1. A Mycobacterium strain characterized by attenuating its virulence upon inactivation of the phoP gene.
 2. A strain of Mycobacterium tuberculosis according to claim 1 characterized by the reduction of virulence in mammal macrophage.
 3. A strain of Mycobacterium tuberculosis according to claim 1 characterized by the reduction of virulence in the mouse experimental model.
 4. A strain of Mycobacterium tuberculosis characterized by the phoP mutant, which is also able of persisting without being eliminated both in the macrophage and in the mouse.
 5. A strain of Mycobacterium tuberculosis characterized by the finding that upon inactivating the phoP gene the regulation of different genes involved in M. tuberculosis virulence is altered.
 6. A strain of Mycobacterium tuberculosis characterized by the finding that the phoP gene protects the mouse against M. tuberculosis infection.
 7. A strain of Mycobacterium characterized by the inactivation of the phoP gene, for which its use as vaccine against human tuberculosis is proposed.
 8. A strain of Mycobacterium characterized by the inactivation of the phoP gene, for which its use as vaccine against tuberculosis in animals is proposed.
 9. A strain of Mycobacterium characterized by the inactivation of the phoP gene, for which its use as possible recombinant vaccine against other pathogens is proposed.
 10. A strain of Mycobacterium characterized by the inactivation of the genes regulated by phoP, for which its use as vaccine against human tuberculosis is proposed.
 11. A strain of Mycobacterium characterized by the inactivation of the genes regulated by phoP, for which its use as vaccine against tuberculosis in animals is proposed.
 12. A strain of Mycobacterium characterized by the inactivation of the genes regulated by phoP, for which its use as possible recombinant vaccine against other pathogens is proposed. 